Thin hollow backlights with beneficial design characteristics

ABSTRACT

A backlight unit ( 10 ) has a hollow cavity ( 16 ) instead of employing a light guide. One or more light sources ( 24   a - c ), such as LEDs, are arranged to emit light into the cavity, which is formed by a front ( 12 ) and a back reflector ( 14 ). The backlight is typically of the edge-lit type. The backlight can have a large area, is thin and consists of fewer components than conventional devices. Its design permits light recycling. The unit emits light of a predefined polarisation and can be arranged to have desired horizontal/vertical viewing angle properties. Light is uniformly distributed within the guide and the light output ( 20   b,    2 Od) is substantially collimated. Such backlights occupy a specific region in a parameter space defined by two parameters: first, the ratio of the output emission area to the total source emission area should lie in the range 0.0001 to 0.1; and second, the ratio of the SEP to the height of the cavity (H) should be in the range 3 to 10, where the SEP is an average plan view source separation, a special measure of the average spacing of light sources in the plane of the unit. There is also a discussion on the required number of light sources N, their arrangement near the periphery of the cavity, as well as the shape and size of the output emission area. A required minimum brightness uniformity (VESA) value to be maintained, when a subset of Madjacent sources is switched off (where M is at least 0.1 N or M&gt;2 or both), is also disclosed. The backlight can be used for a display or for general lighting purposes.

RELATED APPLICATIONS

The following co-owned and copending PCT Patent Applications are incorporated herein by reference: PCT Patent Application No. ______, entitled BACKLIGHT AND DISPLAY SYSTEM USING SAME (Attorney Docket No. 63274WO004); PCT Patent Application No. ______, entitled RECYCLING BACKLIGHTS WITH SEMI-SPECULAR COMPONENTS (Attorney Docket No. 63032WO003); PCT Patent Application No. ______, entitled WHITE LIGHT BACKLIGHTS AND THE LIKE WITH EFFICIENT UTILIZATION OF COLORED LED SOURCES (Attorney Docket No. 63033WO004); and PCT Patent Application No. ______, entitled COLLIMATING LIGHT INJECTORS FOR EDGE-LIT BACKLIGHTS (Attorney Docket No. 63034WO004).

FIELD

The present disclosure relates to extended area light sources suitable for illuminating a display or other graphic from behind, commonly referred to as backlights. The disclosure is particularly suited, but not necessarily limited, to backlights that emit visible light of substantially only one polarization state.

BACKGROUND

Historically, simple backlight devices included only three main components: light sources or lamps, a back reflector, and a front diffuser. Such systems are still in use for general purpose advertising signs and for indoor lighting applications.

Over recent years, refinements have been made to this basic backlight design by adding other components to increase brightness or reduce power consumption, increase uniformity, and/or reduce thickness. The refinements have been fueled by demands in the high-growth consumer electronics industry for products that incorporate liquid crystal displays (LCDs), such as computer monitors, television monitors, mobile phones, digital cameras, pocket-sized MP3 music players, personal digital assistants (PDAs), and other hand-held devices. Some of these refinements, such as the use of solid light guides to allow the design of very thin backlights, and the use of light management films such as linear prismatic films and reflective polarizing films to increase on-axis brightness, are mentioned herein in connection with further background information on LCD devices.

Although some of the above-listed products can use ordinary ambient light to view the display, most include a backlight to make the display visible. In the case of LCD devices, this is because an LCD panel is not self-illuminating, and thus is usually viewed using an illumination assembly or backlight. The backlight is situated on the opposite side of the LCD panel from the viewer, such that light generated by the backlight passes through the LCD to reach the viewer. The backlight incorporates one or more light sources, such as cold cathode fluorescent lamps (CCFLs) or light emitting diodes (LEDs), and distributes light from the sources over an output area that matches the viewable area of the LCD panel. Light emitted by the backlight desirably has sufficient brightness and sufficient spatial uniformity over the output area of the backlight to provide the user with a satisfactory viewing experience of the image produced by the LCD panel.

LCD panels, because of their method of operation, utilize only one polarization state of light, and hence for LCD applications it is important to know the backlight's brightness and uniformity for light of the correct or useable polarization state, rather than simply the brightness and uniformity of light that may be unpolarized. In that regard, with all other factors being equal, a backlight that emits light predominantly or exclusively in the useable polarization state is more efficient in an LCD application than a backlight that emits unpolarized light. Nevertheless, backlights that emit light that is not exclusively in the useable polarization state, even to the extent of emitting randomly polarized light, are still fully useable in LCD applications, since the non-useable polarization state can be easily eliminated by an absorbing polarizer provided at the back of the LCD panel.

LCD devices generally fall within one of three categories, and backlights are used in two of these categories. In a first category, known as “transmission-type,” the LCD panel can be viewed only with the aid of an illuminated backlight. That is, the LCD panel is configured to be viewed only “in transmission,” with light from the backlight being transmitted through the LCD on its way to the viewer. In a second category, known as “reflective-type,” the backlight is eliminated and replaced with a reflective material, and the LCD panel is configured to be viewed only with light sources situated on the viewer-side of the LCD. Light from an external source (e.g., ambient room light) passes from the front to the back of the LCD panel, reflects off of the reflective material, and passes again through the LCD on its way to the viewer. In a third category, known as “transflective-type,” both a backlight and a partially reflective material are placed behind the LCD panel, which is configured to be viewed either in transmission if the backlight is turned on, or in reflection if the backlight is turned off and sufficient ambient light is present.

Backlights described in the detailed description below can generally be used both in transmission-type LCD displays and in transflective-type LCD displays.

Besides the three categories of LCD displays discussed above, backlights can also fall into one of two categories depending on where the internal light sources are positioned relative to the output area of the backlight, where the backlight “output area” corresponds to the viewable area or region of the display device. The “output area” of a backlight is sometimes referred to herein as an “output region” or “output surface” to distinguish between the region or surface itself and the area (the numerical quantity having units of square meters, square millimeters, square inches, or the like) of that region or surface.

In “edge-lit” backlights, one or more light sources are disposed—from a plan-view perspective—along an outer border or periphery of the backlight construction, generally outside the area or zone corresponding to the output area. Often, the light source(s) are shielded from view by a frame or bezel that borders the output area of the backlight. The light source(s) typically emit light into a component referred to as a “light guide,” particularly in cases where a very thin profile backlight is desired, as in laptop computer displays. The light guide is a clear, solid, and relatively thin plate whose length and width dimensions are on the order of the backlight output area. The light guide uses total internal reflection (TIR) to transport or guide light from the edge-mounted lamps across the entire length or width of the light guide to the opposite edge of the backlight, and a non-uniform pattern of localized extraction structures is provided on a surface of the light guide to redirect some of this guided light out of the light guide toward the output area of the backlight. (Other methods of gradual extraction include using a tapered solid guide, where the sloping top surface causes a gradual extraction of light as the TIR angle is, on average, now reached by greater numbers of light rays as the light propagates away from the light source.) Such backlights typically also include light management films, such as a reflective material disposed behind or below the light guide, and a reflective polarizing film and prismatic Brightness Enhancement Films (BEF) film(s) disposed in front of or above the light guide, to increase on-axis brightness.

In the view of Applicants, drawbacks or limitations of existing edge-lit backlights include the following: the relatively large mass or weight associated with the light guide, particularly for larger backlight sizes; the need to use components that are non-interchangeable from one backlight to another, since light guides must be injection molded or otherwise fabricated for a specific backlight size and for a specific source configuration; the need to use components that require substantial spatial non-uniformities from one position in the backlight to another, as with existing extraction structure patterns; and, as backlight sizes increase, increased difficulty in providing adequate illumination due to limited space or “real estate” along the edge of the display, since the ratio of the circumference to the area of a rectangle decreases linearly (1/L) with the characteristic in-plane dimension L (e.g., length, or width, or diagonal measure of the output region of the backlight, for a given aspect ratio rectangle).

In “direct-lit” backlights, one or more light sources are disposed—from a plan-view perspective—substantially within the area or zone corresponding to the output area, normally in a regular array or pattern within the zone. Alternatively, one can say that the light source(s) in a direct-lit backlight are disposed directly behind the output area of the backlight. Because the light sources are potentially directly viewable through the output area, a strongly diffusing plate is typically mounted above the light sources to spread light over the output area to veil the light sources from direct view. Again, light management films, such as a reflective polarizer film, and prismatic BEF film(s), can also be placed atop the diffuser plate for improved on-axis brightness and efficiency. Large area LCD applications tend to use direct-lit backlights because they are not constrained by the 1/L limitation of edge-lit backlights and because of the weight associated with solid light guides.

In the view of Applicants, drawbacks or limitations of existing direct-lit backlights include the following: inefficiencies associated with the strongly diffusing plate; in the case of LED sources, the need for large numbers of such sources for adequate uniformity and brightness, with associated high component cost and heat generation; and limitations on achievable thinness of the backlight beyond which light sources produce non-uniform and undesirable “punchthrough,” where a bright spot appears in the output area above each source.

In some cases, a direct-lit backlight may also include one or some light sources at the periphery of the backlight, or an edge-lit backlight may include one or some light sources directly behind the output area. In such cases, the backlight is considered “direct-lit” if most of the light originates from directly behind the output area of the backlight, and “edge-lit” if most of the light originates from the periphery of the output area of the backlight.

BRIEF SUMMARY

The present application discloses, inter alia, edge-lit backlights that include a front and back reflector that form a hollow light recycling cavity. The recycling cavity has an output area Aout and a characteristic cavity depth H between the cavity output area and the cavity back surface. One or more light sources are disposed proximate a periphery of the backlight to emit light into the light recycling cavity. These light sources can be described by their geometric arrangement relative to one another, including the distances between them, and the way they may be aggregated. For example, planar arrays of light sources can have an average plan view source aggregation of “SEP,” and collectively the light sources have an active emitting area Aemit. The backlights are characterized by a first parameter being in a range from 0.0001 to 0.1 and a second parameter being in a range from 3 to 50, where the first parameter equals Aemit/Aout, and the second parameter equals SEP/H. The light sources may be arranged predominantly at a periphery of the output area to provide an edge-lit backlight, or arranged predominantly within the space of the output area to provide a direct-lit backlight. Backlights within the recited first and second parameter ranges can have any suitable physical size, large or small. For example, such a backlight may be on the order of an inch in lateral dimension (e.g., diagonal measure of a rectangular output area), and in such case may be one of many partitioned zones in a larger zoned backlight.

The application also discloses edge-lit backlights having a front and back reflector that form a hollow recycling cavity, and that can be relatively large regardless of their first and second parameter values. The front reflector, which is partially transmissive, provides an output area of the backlight that may be generally rectangular in shape. A diagonal measure of the rectangular shape can be any suitable value. In some embodiments, the diagonal can be at least 12 inches (300 mm). The hollow cavity can advantageously reduce the mass of the backlight relative to an edge-lit backlight that uses a solid light guide.

The application also discloses backlights in which light is distributed so effectively and efficiently in transverse or lateral directions that the backlights are highly resistant to the visible effects of source failure and/or source-to-source color variability. The brightness uniformity over the output area of such a backlight is only modestly diminished when individual light sources within the backlight degrade, fail, or are turned off. For example, backlights are disclosed in which a number N of light sources emit light into a recycling cavity formed between a front and back reflector, with some of the emitted light passing through the front reflector to form the output area of the backlight. The number N can be at least 8, and the N light sources include a subset of M light sources that are adjacent to each other, where M is at least 10% of N, or is at least 2, or both. The backlight maintains adequate brightness uniformity over the output area both when all N light sources are energized and when all of the M light sources are selectively turned off. Because of the excellent lateral or transverse light distribution (“light mixing”) in the recycling cavity, backlights such as this are also typically less sensitive to problems associated with color variability among LED sources that are all nominally the same color. This color variability typically requires that LEDs be binned.

In many cases, it is desirable to provide very high recycling cavities, where the front reflector has a hemispherical reflectivity for visible unpolarized light of R^(f) _(hemi), the back reflector has a hemispherical reflectivity for visible unpolarized light of R^(b) _(hemi), and the product R_(emi)*R^(b) _(hemi) is at least 0.70. For example, if the back reflector has an R^(b) _(nemi) of 98%, then the front reflector has an R^(f) _(hemi) of at least 71.4%. If the front reflector is optionally fabricated to reflect and transmit different polarization states differently, it may then have a hemispherical reflectivity for visible light of a first polarization state of 98%, and a hemispherical reflectivity for visible light of a second polarization state (e.g., the useable polarization state) orthogonal to the first polarization state of 78%. In such a case, the second or useable polarization state is predominantly reflected by the front reflector even though it is preferentially transmitted in comparison to the first polarization state.

It is also often desirable to ensure that the amount of light transmitted through the front reflector is substantially greater than the amount of light transmitted or otherwise lost (e.g., by absorption) by the back reflector. Thus, for example, the ratio of (1−R^(f) _(hemi))/(1−R^(b) _(hemi)) is at least 10.

Besides the front and back reflectors, highly reflective and low loss side reflectors are preferably provided to yield a substantially closed or sealed reflecting cavity, and losses associated with the light sources are kept to minimal levels by, for example, maintaining a very small ratio of collective source area to backlight output area. In some instances, highly reflective and low loss side reflectors can aid in the lateral and transverse transport and mixing of light in a high recycling cavity.

These and other aspects of the present application will be apparent from the detailed description below. In no event, however, should the above summaries be construed as limitations on the claimed subject matter, which subject matter is defined solely by the attached claims, as may be amended during prosecution.

BRIEF DESCRIPTION OF THE DRAWINGS

Throughout the specification reference is made to the appended drawings, where like reference numerals designate like elements, and wherein:

FIG. 1 is a schematic side view of a generalized recycling backlight or similar extended area source;

FIGS. 2 a-c are top plan views of different light source arrangements within a recycling cavity;

FIG. 3 is a graph of a backlight parameter design space defined by two dimensionless parameters, Parameter A and Parameter B;

FIG. 4 is a graph of backlight parameter design space with points plotted corresponding to a variety of commercially available LCD display devices;

FIG. 5 is a perspective view of a surface, showing different planes of incidence and different polarization states;

FIG. 6 is a front view of a backlight output area;

FIG. 7 is a schematic cross-section of a display system that includes a backlight in combination with an LCD panel;

FIG. 8 is a plan view of an LED cluster arrangement;

FIG. 9 is a graph showing average luminance for different reflectors and different “effective reflectivities” of the back reflector; and

FIGS. 10 and 11 are graphs that plot the various backlight examples in the Parameter A/Parameter B design space, with FIG. 10 plotting edge-lit backlights and FIG. 11 plotting direct-lit backlights.

DETAILED DESCRIPTION

It would be beneficial for next generation backlights to combine some or all of the following characteristics while providing a brightness and spatial uniformity that is adequate for the intended application: thin profile; design simplicity, such as a minimal number of optical components and a minimal number of sources, and convenient source layout; low weight; no use of or need for film components having substantial spatial non-uniformities from one position in the backlight to another (e.g., no significant gradation); compatibility with LED sources, as well as other small area, high brightness sources such as solid state laser sources; insensitivity to problems associated with color variability among LED sources that are all nominally the same color; to the extent possible, insensitivity to the burnout or other failure of a subset of LED sources; and the elimination or reduction of at least some of the limitations and drawbacks mentioned in the Background section above.

Whether these characteristics can be successfully incorporated into a backlight depends in part on the type of light source used for illuminating the backlight. CCFLs, for example, provide white light emission over their long narrow active emissive areas, and those emissive areas can also operate to scatter some light impinging on the CCFL, such as would occur in a recycling cavity. The typical emission from a CCFL, however, has an angular distribution that is substantially Lambertian, which may be inefficient or otherwise undesirable in a given backlight design. Also, the emissive surface of a CCFL, although somewhat diffusely reflective, also typically has an absorptive loss that Applicants have found to be significant if a highly recycling cavity is desired.

An LED die emits light in a near-Lambertian manner, but because of its much smaller size relative to CCFLs, the LED light distribution can be readily modified, e.g., with an integral encapsulant lens or reflector or extractor to make the resulting packaged LED a forward-emitter, a side-emitter, or other non-Lambertian profile. Such non-Lambertian profiles can provide important advantages for the disclosed backlights. However, the smaller size and higher intensity of LED sources relative to CCFLs can also make it more difficult to produce a spatially uniform backlight output area using LEDs. This is particularly true in cases where individual colored LEDs, such as arrangements of red/green/blue (RGB) LEDs, are used to produce white light, since failure to provide adequate lateral transport or mixing of such light can easily result in undesirable colored bands or areas. White light emitting LEDs, in which a phosphor is excited by a blue or UV-emitting LED die to produce intense white light from a small area or volume on the order of an LED die, can be used to reduce such color non-uniformity, but white LEDs currently are unable to provide LCD color gamuts as wide as those achievable with individual colored LED arrangements, and thus may not be desirable for all end-use applications.

Applicants have discovered combinations of backlight design features that are compatible with LED source illumination, and that can produce backlight designs that outperform backlights found in state-of-the-art commercially available LCD devices in at least some respects. These backlight design features include some or all of the following:

-   -   a recycling optical cavity in which a large proportion of the         light undergoes multiple reflections between substantially         coextensive front and back reflectors before emerging from the         front reflector, which is partially transmissive and partially         reflective;     -   overall losses for light propagating in the recycling cavity are         kept extraordinarily low, for example, both by providing a         substantially enclosed cavity of low absorptive loss, including         low loss front and back reflectors as well as side reflectors,         and by keeping losses associated with the light sources very         low, for example, by ensuring the cumulative emitting area of         all the light sources is a small fraction of the backlight         output area;     -   a recycling optical cavity that is hollow, i.e., the lateral         transport of light within the cavity occurs predominantly in         air, vacuum, or the like rather than in an optically dense         medium such as acrylic or glass;     -   in the case of a backlight designed to emit only light in a         particular (useable) polarization state, the front reflector has         a high enough reflectivity for such useable light to support         lateral transport or spreading, and for light ray angle         randomization to achieve acceptable spatial uniformity of the         backlight output, but a high enough transmission into the         appropriate application-useable angles to ensure application         brightness of the backlight is acceptable;     -   the recycling optical cavity contains a component or components         that provide the cavity with a balance of specular and diffuse         characteristics, the component having sufficient specularity to         support significant lateral light transport or mixing within the         cavity, but also having sufficient diffusivity to substantially         homogenize the angular distribution of steady state light within         the cavity, even when injecting light into the cavity only over         a narrow range of angles (and further, in the case of a         backlight designed to emit only light in a particular (useable)         polarization state, recycling within the cavity preferably         includes a degree of randomization of reflected light         polarization relative to the incident light polarization state,         which allows a mechanism by which non-useable polarized light is         converted into useable polarized light);     -   the front reflector of the recycling cavity has a reflectivity         that generally increases with angle of incidence, and a         transmission that generally decreases with angle of incidence,         where the reflectivity and transmission are for unpolarized         visible light and for any plane of incidence, and/or for light         of a useable polarization state incident in a plane for which         oblique light of the useable polarization state is p-polarized         (and further, the front reflector has a high value of         hemispheric reflectivity while also having a sufficiently high         transmission of application-useable light);     -   light injection optics that partially collimate or confine light         initially injected into the recycling cavity to propagation         directions close to a transverse plane (the transverse plane         being parallel to the output area of the backlight), e.g., an         injection beam having a full angle-width (about the transverse         plane) at half maximum power (FWHM) in a range from 0 to 90         degrees, or 0 to 60 degrees, or 0 to 30 degrees. In some         instances it may be desirable for the maximum power of the         injection light to have a downward projection, below the         transverse plane, at an angle with the transverse plane of no         greater than 40 degrees, and in other instances, to have the         maximum power of the injected light to have an upwards         projection, above the transverse plane towards the front         reflector, at an angle with the transverse plane of no greater         than 40 degrees.

Backlights for LCD panels, in their simplest form, consist of light generation surfaces such as the active emitting surfaces of LED dies or the outer layers of phosphor in a CCFL bulb, and a geometric and optical arrangement of distributing or spreading this light in such a way as to produce an extended- or large-area illumination surface or region, referred to as the backlight output area, which is spatially uniform in its emitted brightness. Generally, this process of transforming very high brightness local sources of light into a large-area uniform output surface results in a loss of light because of interactions with all of the backlight cavity surfaces, and interaction with the light-generation surfaces. Other approaches such as using direct-lit source architectures with specified LED lenses to level the incident first bounce flux on the front reflector can result in efficient, uniform brightness through the backlight output surface, but these approaches can be very sensitive to the exactly geometrical configuration of all of the backlight components. To a first approximation, any light that is not delivered by this process through the output area or surface associated with a front reflector—optionally into a desired application viewer-cone (if any), and with a particular (e.g., LCD-useable) polarization state (if any)—is “lost” light.

We propose that any backlight containing a recycling cavity can be uniquely characterized by two essential parameters. In this regard, reference is made to the generalized backlight 10 shown in FIG. 1, in which a front reflector 12 and a back reflector 14 form a recycling cavity 16. The backlight 10 emits light over an extended output area or surface 18, which in this case corresponds to an outer major surface of the front reflector 12. The front and back reflectors 12, 14 are shown plane and parallel to each other, and coextensive over a transverse dimension 13, which dimension also corresponds to a transverse dimension such as a length or width of the output area 18.

In other embodiments, the front and back reflectors 12, 14 can be non-parallel, e.g., as is further described in co-owned U.S. Patent Application Ser. No. 61/030,767 entitled BACKLIGHTS HAVING SELECTED OUTPUT LIGHT FLUX DISTRIBUTION AND DISPLAY SYSTEMS USING SAME. This non-parallel relationship can be provided using any suitable technique. For example, one or both of the top and bottom reflectors can be formed into non-planar shapes, the front and back reflectors can be positioned such that they are non-parallel, one or more structures can be positioned on one or both of the front and back reflectors, or any combination of these techniques can be utilized to provide a non-parallel relationship.

The front reflector reflects a substantial amount of light incident upon it from within the cavity, as shown by an initial light beam 20 being reflected into a relatively strong reflected beam 20 a and a relatively weaker transmitted beam 20 b. Note that the arrows representing the various beams are schematic in nature, e.g., the illustrated propagation directions and angular distributions of the different beams are not intended to be completely accurate. Returning to the figure, reflected beam 20 a is strongly reflected by back reflector 14 into a beam 20 c. Beam 20 c is partially transmitted by front reflector 12 to produce transmitted beam 20 d, and partially reflected to produce another beam (not shown). The multiple reflections between the front and back reflectors help to support transverse propagation of light within the cavity, indicated by arrow 22. The totality of all transmitted beams 20 b, 20 d, and so on add together incoherently to provide the backlight output.

For illustrative purposes, small area light sources 24 a, 24 b, 24 c are shown in alternative positions in the figure, where source 24 a is shown in an edge-lit position and is provided with a reflective structure 26 that can help to collimate (at least partially) light from the source 24 a. Sources 24 b and 24 c are shown in direct-lit positions, and source 24 c would generally be aligned with a hole or aperture (not shown) provided in the back reflector 14 to permit light injection into the cavity 16. Reflective side surfaces (not shown, other than reflective structure 26) would typically also be provided generally at the endpoints of dimension 13, preferably connecting the front and back reflectors 12, 14 in a sealed fashion for minimum losses.

Any suitable technique can be used to seal together the front and back reflectors. For example, in some embodiments, a reflective caulk can be used to seal the front and back reflectors 12, 14 together. The reflective caulk can provide a reflective barrier to prevent light leakage from the backlight cavity and provide a mechanical bond to secure together the front and back reflectors 12, 14. Any suitable reflective caulk can be utilized. For example, the caulk can include a clear matrix that is loaded with reflective particles and/or may contain regions of differing refractive index. Suitable particles include TiO₂ or ribbons or flakes of reflective materials, such as metal chips, metallized polymer films, nacreous pigments, or multilayer optical films. The clear matrix may be of any material suitable to encapsulate and deliver the reflective elements along with providing sufficient bond strength to the applied surfaces. Regions of differing refractive index may be formed through an immiscible blend chemistry, loading of glass or polymer beads, or the injection of air or other dissimilar materials into the matrix. The caulk may be dispensed through a nozzle to form a bead or other shaped profile. A convex or concave cross-sectional profile may offer additional design options for managing the light inside the backlight cavity. The caulk may be thermally or optically cured. In some embodiments, the caulk may include an epoxy type system with suitable viscosity for dispensing and shape retention.

In some direct-lit embodiments, generally vertical reflective side surfaces may actually be thin partitions that separate the backlight from similar or identical neighboring backlights, where each such backlight is actually a portion of a larger zoned backlight. Light sources in the individual sub-backlights can be turned on or off in any desired combination to provide patterns of illuminated and darkened zones for the larger backlight. Such zoned backlighting can be used dynamically to improve contrast and save energy in some LCD applications. The reflective partitions between zones may not extend completely to the top reflector, but may be separated therefrom by a gap that is sized to minimize the visibility of zone boundaries (from the perspective of a viewer) while also optimizing zone-to-zone bleedthrough.

Returning to our two-parameter discussion, the first parameter, referred to herein as Parameter A, relates the total emitting source area to the backlight output area. Thus, Parameter A is the ratio of the total area of all emitting light source surfaces (referred to herein as “Aemit”) to the area of the output surface of the backlight (referred to herein as “Aout”). In the usual case of a rectangular-shaped output region, the area Aout is simply the rectangle's length times its width. For a given backlight, the total area of the light source surfaces can be determined by summing the active area of the light sources. For example, a Lumileds™ LXHL-PM09 green LED, considered a “large die” LED, has a die surface area (one large top surface and four smaller side surfaces) of about 1 mm². A Nichia Rigel NFSG036B green LED, considered a “small die” LED, has a die surface area of about 0.09 mm². A backlight having an array that consists of 65 “large die” LED clusters—one red, one blue, and one green, whose outputs are balanced to produce white light when combined—would have a total light source surface area of

Aemit=65 clusters×3 dies/cluster×1 mm²/die=195 mm².

For a CCFL-based backlight, the total light-generation surface area is merely the total surface area of the light-emitting phosphor layer per bulb, times the number of bulbs illuminating the cavity. For example, a backlight containing 16 CCFL bulbs, each 820 mm long with a 4 mm diameter, would have a total light generation surface area of

Aemit=16 bulbs×(π×4 mm)×820 mm=164,871 mm².

The ratio of the cumulative light source surface area to the output surface area, i.e., Parameter A, is a normalized and unitless measure representative of a basic backlight challenge: transforming small surfaces of high brightness (and typically with a Lambertian emission pattern) into a large surface output, preferably of relatively spatially uniform brightness, and preferably where the total luminous flux from the output surface is a substantial fraction of the total luminous flux from the light sources (a fraction of 1.0 or 100% corresponding to an ideal lossless system).

Our second parameter relates the average plan-view or lateral source aggregation (“SEP”) to the cavity depth (“H”). The cavity depth H (FIG. 1) is the physical distance from the back reflector to the front reflector (output area Aout) along an axis perpendicular to the output area, i.e., it is the on-axis separation of the front and back reflectors. The cavity depth H can also be interpreted as the average separation between a non-planar output area and a non-planar back reflector. The average plan-view source separation SEP is a measure of the characteristic lateral spacing of light sources relative to the output surface Aout. The parameter SEP measures the degree to which the light sources are disposed in a uniform spatial distribution within the cavity relative to the output surface. Larger values of the aggregation characteristic SEP indicate light sources are “clumped” or confined within relatively small areas (volumes) of the cavity, while smaller values of SEP indicate light-source spacings that are uniformly arranged relative to the output surface. In general, light sources within hollow cavities are arranged to provide as spatially uniform a distribution of light flux on the output surface as is possible, resulting in minimum values of SEP for a given cavity geometry. Computation of SEP is best explained by examples.

FIG. 2 a shows a schematic plan view of a light source arrangement for a direct-lit backlight 30 a having eighteen light sources 32 a disposed on or proximate a back reflector 34 of transverse dimensions L (length) and W (width), where the associated front reflector and output area (not shown) have the same transverse dimensions and are coextensive with the back reflector 34. The sources 32 a are arranged in a regular repeating pattern to form three equally spaced rows separated along the width or y-direction and six equally spaced columns separated along the length or x-direction (perpendicular to the y-direction). The average spacing of the sources along the x-direction is thus L/6, and the average spacing of the sources along the y-direction is W/3. The SEP is then calculated as the average of these two orthogonal source spacings, or

SEP=((L/6)+(W/3))/2.

For a 6×6 inch output area (L=W=6 inches or 153 mm), the SEP for this example becomes SEP=38 mm. Note that the result remains the same if the spacing between rows is not uniform, or if the spacing between columns is not uniform, as long as the light sources are arranged in three rows and three columns. SEP can be approximately evaluated for slightly irregular spacing along rows and columns by assuming row and column alignment.

Note also that each source 32 a may be a single emitting element such as a single white-emitting LED, or it may be the smallest unit cell or cluster of individual colored LEDs (e.g., red/green/blue or red/green/blue/green, etc.) that produces the desired backlight color, which is normally white light. In the case of a backlight designed to emit light of only one color, e.g., green, each source 32 a is a single green-emitting LED.

FIG. 2 b shows a schematic plan view of a light source arrangement for a backlight 30 b similar to backlight 30 a, but where eighteen light sources 32 b are disposed along a periphery of the back reflector 34 in a single line or column parallel to the y-direction. In this case there is only one column of light sources 32 b along the length or x-direction, and 18 rows of (single) light sources 32 b arranged along the width or y-direction. The average spacing of the sources along the x-direction is thus L/1, and the average spacing of the sources along the y-direction is W/18. The SEP is again calculated as the average of these two orthogonal source spacings, or

SEP=((L/1)+(W/18))/2.

For a 6×6 inch output area (L=W=6 inches or 153 mm), the SEP for this example becomes SEP=81 mm. Note that the result remains the same if the spacing of the sources along the y-direction is not uniform. The SEP value of 81 mm is more than twice that of the FIG. 2 a embodiment (38 mm), even though both embodiments use the same number of sources. This is as it should be, since each light source in the FIG. 2 b embodiment is required to influence or illuminate a much longer lateral dimension along the output surface than each source in FIG. 2 a, as the light sources are more aggregated as compared with FIG. 2 a. SEP can alternatively be considered a transverse or lateral “radius of influence” that each source, on average, is required to provide to the output area.

In a case were there is only one light source 32 a in the embodiment of FIG. 2 a, or only one light source 32 b in the embodiment of FIG. 2 b, no matter where in relation to the output area the single light source is positioned, the average source spacing along the x-direction is L/1 and the average source spacing along the y-direction is W/1, resulting in an SEP of ((L+W)/2) or 153 mm in the case of a 6×6 inch output area.

Linear-shaped light sources such as CCFLs that span substantially a full transverse dimension of the output area are treated differently than localized or “point” sources like LEDs. FIG. 2 c shows a schematic plan view of a light source arrangement for a direct-lit backlight 30 c similar to backlight 30 a, but where six linear light sources 32 c are arranged in a linear array across the same back reflector 34 as shown. In this case the average spacing of the sources along the x-direction is L/6, because there are six sources distributed along the dimension L. The average spacing along the y-direction is zero because the light sources 32 c are continuous along that direction. SEP is again calculated as the average of these two orthogonal source spacings, or

SEP=((L/6)+0)/2=L/12.

This corresponds to half the average bulb-to-bulb spacing. For a 6×6 inch output area (L=W=6 inches or 153 mm), the SEP for this example becomes SEP=13 mm.

With this background, we can characterize any recycling cavity backlight, which has adequate brightness and spatial uniformity for its intended application, by the two dimensionless parameters

Parameter A=Aemit/Aout; and

Parameter B=SEP/H

where Aemit, Aout, SEP, and H are as described above. FIG. 3 shows a graph that plots these two parameters as a backlight parameter space or backlight design space.

This characterization is particularly straightforward for planar backlight cavities, in which the back reflector (sometimes referred to herein as a backplane) of the backlight and the output area of the backlight are both planar, parallel to each other, and of approximately equal area and approximately coextensive. Our two-parameter characterization, however, is by no means restricted to plane parallel backlight geometries, and may be generalized for any backlight geometry having the basic elements of an output surface associated with a front reflector, and a back reflector that forms a light recycling cavity with the front reflector, and a grouping of one or more light sources disposed within, or optically connected to the cavity.

In addition, the determination of the characteristic light-source spacing parameter SEP has been illustrated above for light sources with substantially regular spacing along the x and y directions. For instances in which the light sources are disposed in an irregular pattern, SEP can be determined by the following equation:

${{SEP} = {{\frac{\left( {A_{out} - {\sum\limits_{{i = 1},N}A_{i}}} \right)}{A_{out}}\sqrt{\frac{A_{out}}{N}}} + {\sum\limits_{{i = 1},N}{\frac{A_{i}}{A_{out}}\sqrt{\frac{A_{i}}{\#_{i}}}}}}},$

where A_(i) is the area of a circle i, circumscribing two or more irregularly spaced light sources, the number of light sources in the circumscribing circle being #_(i). N is the total number of circumscribing circles used to encompass all the light sources, where the number and location of all of the circumscribing circles, i through N, are chosen so as to minimize the sum of all the circumscribing circles' aggregate area,

$\sum\limits_{{i = 1},N}{A_{i}.}$

As an example, referring to FIG. 2 b, if the 18 light sources disposed in a single column along the y-direction were confined to the lower ½ of the y dimension, their spacing along the y-axis would be non-uniform, i.e., spaced at W/36 in the lower ½ of the axis, and no light sources in the upper ½ of the axis. In this instance, use of the SEP equation for irregular spacing gives SEP=125 mm. So as the light sources are more spatially aggregated, the characteristic aggregation parameter, SEP, increases to 125 mm.

If the confinement or aggregation of the 18 light sources were to continue to occupy an ever smaller region along the y-axis, the SEP equation for irregular spacing will provide a larger dimension approaching a maximum of 153 mm, as describe above, for the instance of a single light source residing in the 6×6 inch cavity.

FIG. 3 includes some description of general trends in the design space, which is self-explanatory. Also depicted is a point 36 representing a hypothetical initial backlight design. If the design is modified by reducing the cavity depth H but keeping all other design features constant, the modified design will correspond to a point 36 a above and in vertical alignment with point 36. If the initial backlight design is instead modified by replacing each individual source in the backlight with a smaller emitting area source (e.g., replacing each LED die with a smaller LED die, but keeping the total number of LED dies constant and keeping their spatial distribution the same), but keeping all other design features constant, then the modified design will correspond to a point 36 b to the left of and in horizontal alignment with point 36. In yet another alternative, the initial design can be modified by adding more light sources and arranging them more densely within the backlight, while keeping other design features constant. In this case the modified design will correspond to a point 36 c that is both below and to the right of the starting point 36. One can anticipate that in the years to come, LED sources may become brighter, and this may lead one to remove light sources from the initial design and arrange them more sparsely within the backlight, keeping other design features constant. Such a design modification would correspond to a point that is both above and to the left of the starting point 36.

Several commercially available LCD devices were obtained and their backlights analyzed with regard to the backlight parameter space. The resulting design points are shown in the backlight design space graph illustrated in FIG. 4, which again plots Parameter A against Parameter B.

Points 40 a-d all represent commercial LCD televisions that utilize direct-lit backlights powered by arrays of colored LEDs. Point 40 a represents a Samsung Electronics 46 inch (diagonal measure) TV. Point 40 b represents a 32 inch Sony LED TV, employing high-brightness OSRAM Golden Dragon LEDs. This unit grouped the LEDs in clusters of four (RGGB). Point 40 c represents another Sony 32 inch LED TV using OSRAM Golden Dragon LEDs, but this one grouped the LEDs in clusters of three: RGB. Point 40 d represents a Sony Qualia 40 inch TV. The points 40 a-d all have a Parameter B value of very nearly 2.

Points 40 e-f represent displays for commercial notebook computers. These each used an edge-lit backlight configuration, CCFL sources, and solid (acrylic) light guides. Point 40 e represents an HP 14.1 inch dv1000, for Samsung LTN140W1-101. Point 40 f represents an AUO 15.4 inch notebook computer, type B154-EW-02.

Points 40 g represent numerous commercial LCD televisions, each of which used a direct-lit backlight illuminated with CCFLs.

Reviewing the plotted points in FIG. 4, one can see that backlights having the smallest values of Parameter A (points 40 a-d), i.e., the smallest fraction of collective source emission area to backlight output region area, have relatively low values of Parameter B. Sources that have a high value of Parameter B (points 40 e-f), i.e., thin cavity depth in relation to the average source separation, utilize solid light guides with their accompanying disadvantages, and achieve only moderately low values of Parameter A (since they utilize CCFL sources).

It would be desirable to provide a class of backlights having thin cavities (e.g., Parameter B=3 or more), and having moderate to low or even very low relative source areas (Parameter A=0.1 or less), and having a hollow cavity rather than a solid light guide.

As mentioned herein, Applicants have discovered combinations of backlight design features that are compatible with LED source illumination, and that can produce backlight designs that outperform existing backlights in at least some respects. We will now discuss some of these backlight design features in more detail, and then, with reference to backlights that have been constructed and tested, demonstrate that such backlights (utilizing hollow cavity designs) are now able to occupy a desirable space on the graph of FIG. 4.

We begin with a discussion of exemplary front and back reflectors. In this regard, reference is made generally PCT Patent Application No. ______, entitled BACKLIGHT AND DISPLAY SYSTEM USING SAME (“the 63274 Application”).

Exemplary partial reflectors (front reflectors) we describe here—particularly, for example, the asymmetric reflective films (ARFs) described in the 63274 Application—provide for low loss reflections and also for better control of transmission and reflection of polarized light than is possible with TIR in a solid light guide alone. Thus, in addition to improved light distribution in a lateral sense across the face of the display, the hollow light guide can also provide for improved polarization control for large systems. Significant control of transmission with angle of incidence is also possible with the preferred ARFs mentioned above. In this manner, light from the mixing cavity can be collimated to a significant degree, and a polarized light output from a single film construction can be provided.

Preferred front reflectors have a relatively high overall reflectivity to support relatively high recycling within the cavity. We characterize this in terms of “hemispheric reflectivity,” meaning the total reflectivity of a component (whether a surface, film, or collection of films) when light is incident on it from all possible directions. Thus, the component is illuminated with light incident from all directions (and all polarization states, unless otherwise specified) within a hemisphere centered about a normal direction, and all light reflected into that same hemisphere is collected. The ratio of the total flux of the reflected light to the total flux of the incident light for a wavelength range of interest yields the hemispheric reflectivity, R_(hemi). Characterizing a reflector in terms of its R_(hemi) is especially convenient for recycling cavities because light is generally incident on the internal surfaces of the cavity—whether the front reflector, back reflector, or side reflectors—at all angles. Further, unlike the reflectivity for normal incidence, R_(hemi) is insensitive to, and already takes into account, the variability of reflectivity with incidence angle, which may be very significant for some components (e.g., prismatic films).

In fact, in exemplary embodiments, preferred front reflectors exhibit a (direction-specific) reflectivity that increases with incidence angle away from the normal (and a transmission that generally decreases with angle of incidence), at least for light incident in one plane. Such reflective properties cause the light to be preferentially transmitted out of the front reflector at angles closer to the normal, i.e., closer to the viewing axis of the backlight. This helps to increase the perceived brightness of the display at viewing angles that are important in the display industry (at the expense of lower perceived brightness at higher viewing angles, which are less common but as important). We say that the increasing reflectivity with angle behavior is “at least for light incident in one plane,” because sometimes a narrow viewing angle is desired for only one viewing plane, and a wider viewing angle is desired in the orthogonal plane. An example is some LCD TV applications, where a wide viewing angle is desired for viewing in the horizontal plane, but a narrower viewing angle is specified for the vertical plane. In other cases, narrow angle viewing is desirable in both orthogonal planes so as to maximize on-axis brightness.

When we discuss oblique angle reflectivity, it is helpful to keep in mind the geometrical considerations of FIG. 5. There, we see a surface 50 that lies in an x-y plane, with a z-axis normal direction. If the surface is a polarizing film or partially polarizing film (such as the ARFs described in the 63274 Application), we designate for purposes of this application the y-axis as the “pass axis” and the x-axis as the “block axis.” In other words, if the film is a polarizing film, normally incident light whose polarization axis is parallel to the y-axis is preferentially transmitted compared to normally incident light whose polarization axis is parallel to the x-axis. Of course, in general, the surface 50 need not be a polarizing film.

Light can be incident on surface 50 from any direction, but we concentrate on a first plane of incidence 52, parallel to the x-z plane, and a second plane of incidence 54, parallel to the y-z plane. “Plane of incidence” of course refers to a plane containing the surface normal and a particular direction of light propagation. We show in the figure one oblique light ray 53 incident in the plane 52, and another oblique light ray 55 incident in the plane 54. Assuming the light rays to be unpolarized, they will each have a polarization component that lies in their respective planes of incidence (referred to as “p-polarized” light and labeled “p” in the figure), and an orthogonal polarization component that is oriented perpendicular to the respective plane of incidence (referred to as “s-polarized light” and labeled “s” in the figure). It is important to note that for polarizing surfaces, “s” and “p” can be aligned with either the pass axis or the block axis, depending on the direction of the light ray. In the figure, the s-polarization component of ray 53, and the p-polarization component of ray 55, are aligned with the pass axis (the y-axis) and thus would be preferentially transmitted, while the opposite polarization components (p-polarization of ray 53, and s-polarization of ray 55) are aligned with the block axis.

With this in mind, let us consider the meaning of specifying (if we desire) that the front reflector “exhibit a reflectivity that generally increases with angle of incidence,” in the case where the front reflector is an ARF such as is described in the 63274 Application. The ARF includes a multilayer construction (e.g., coextruded polymer microlayers that have been oriented under suitable conditions to produce desired refractive index relationships and desired reflectivity characteristics) having a very high reflectivity for normally incident light in the block polarization state and a lower but still substantial reflectivity (e.g., 25 to 90%) for normally incident light in the pass polarization state. The very high reflectivity of block-state light (p-polarized component of ray 53, and s-polarized component of ray 55) generally remains very high for all incidence angles. The more interesting behavior is for the pass-state light (s-polarized component of ray 53, and p-polarized component of ray 55), since that exhibits an intermediate reflectivity at normal incidence. Oblique pass-state light in the plane of incidence 52 will exhibit an increasing reflectivity with increasing incidence angle due to the nature of s-polarized light reflectivity (the relative amount of increase, however, will depend on the initial value of pass-state reflectivity at normal incidence). Thus, light emitted from the ARF film in a viewing plane parallel to plane 52 will be partially collimated or confined in angle. Oblique pass-state light in the other plane of incidence 54 (i.e., the p-polarized component of ray 55), however, can exhibit any of three behaviors depending on the magnitude and polarity of the z-axis refractive index difference between microlayers relative to the in-plane refractive index differences, as discussed in the 63274 Application.

In one case, a Brewster angle exists, and the reflectivity of this light decreases with increasing incidence angle. This produces bright off-axis lobes in a viewing plane parallel to plane 54, which are usually undesirable in LCD viewing applications (although in other applications this behavior may be acceptable, and even in the case of LCD viewing applications this lobed output may be redirected towards the viewing axis with the use of a prismatic film and such).

In another case, a Brewster angle does not exist or is very large, and the reflectivity of the p-polarized light is relatively constant with increasing incidence angle. This produces a relatively wide viewing angle in the referenced viewing plane.

In the third case, no Brewster angle exists, and the reflectivity of the p-polarized light increases significantly with incidence angle. This can produce a relatively narrow viewing angle in the referenced viewing plane, where the degree of collimation is tailored at least in part by controlling the magnitude of the z-axis refractive index difference between microlayers in the ARF.

Of course, the reflective surface 50 need not have asymmetric on-axis polarizing properties as with ARF. Symmetric multilayer reflectors, for example, can be designed to have a high reflectivity but with substantial transmission by appropriate choice of the number of microlayers, layer thickness profile, refractive indices, and so forth. In such a case, the s-polarized components of both ray 53 and 55 will increase with incidence angle, in the same manner with each other. Again, this is due to the nature of s-polarized light reflectivity, but the relative amount of increase will depend on the initial value of the normal incidence reflectivity. The p-polarized components of both ray 53 and ray 55 will have the same angular behavior as each other, but this behavior can be controlled to be any of the three cases mentioned above by controlling the magnitude and polarity of the z-axis refractive index difference between microlayers relative to the in-plane refractive index differences, as discussed in the 63274 Application.

Thus, we see that the increase in reflectivity with incidence angle (if present) in the front reflector can refer to light of a useable polarization state incident in a plane for which oblique light of the useable polarization state is p-polarized. Alternately, such increase in reflectivity can refer to the average reflectivity of unpolarized light in any plane of incidence.

Reflective (but partially transmissive) components other than the specific ARF multilayer reflective films can also be used. Alternative candidate materials include the following:

REFLECTOR TYPE CONSTRUCTION POLARIZATION Multilayer ¼ wave birefringent films, Polarizing asymmetric orientation ¼ wave birefringent films, Non-polarizing @ 0 symmetric orientation degrees Pile of plates birefringent films, Polarizing asymmetric orientation ¼ wave isotropic films Non-polarizing @ 0 degrees Pile of plates films, isotropic Non-polarizing Perforated mirrors Non-polarizing Locally thinned partial reflectors Polarizing or non- (light transmission is increased polarizing in the thinned region) Crossed Reflective Polarizers Polarizing (angle of crossing controls amount of transmitted light) Metal Thin film enhanced metal films Non-polarizing Thin film enhanced metal films, Non-polarizing perforated Wire grid Polarizing Diffusive Inorganic filled polymer films Non-polarizing Voided polymer films Non-polarizing Polymer foams Non-polarizing Polymer blends Non-polarizing Polymer blends Polarizing Asymmetric DRPF Mirrors Non-polarizing Asymmetric DRPF Polarizers Polarizing Birefringent fibers - concentric Polarizing Islands-in-sea birefringent fibers Polarizing Holographic Diffusers Non-polarizing Microstructured Lenticular structures or linear Non-polarizing prisms 2D structured surfaces (cube Non-polarizing corner, lenslet arrays, etc.) Cholesteric (with Lefthand Polarizing retarder films) Righthand Polarizing Combinations of both Polarizing - adjustable Metal/Dielectric Metal/dielectric layered mirrors Non-polarizing

The above-mentioned reflectors can be used alone or in combination to provide suitable front reflectors.

Preferred back reflectors also have a high hemispherical reflectivity for visible light, typically, much higher than the front reflector, since the front reflector is deliberately designed to be partially transmissive to provide the required light output of the backlight. Reference is again made to the 63274 Application. The hemispherical reflectivity of the back reflector is referred to as R^(b) _(hemi), while that of the front reflector is referred to as R^(f) _(hemi). Preferably, the product R^(f) _(hemi)*R^(b) _(hemi) is at least 70% (0.70), or 75%, or 80%.

Preferably, the front and/or back reflector can have a balance of specular and diffuse characteristics, thus having a semi-specular reflection characteristic as described more fully in commonly assigned PCT Patent Application No. ______, entitled RECYCLING BACKLIGHTS WITH SEMI-SPECULAR COMPONENTS (Attorney Docket No. 63032WO003) (“the 63032 Application”). Such reflectors have a transport ratio T of greater than 15% at a 15 degree incidence angle and less than 95% at a 45 degree incidence angle, where T=(F−B)/(F+B), and F and B refer to forward- and backward-scattered light flux at a specified incidence angle. Incorporation of such semi-specular reflectors into the recycling cavity can provide a desirable balance between lateral transport and angular mixing of light in the recycling cavity for optimal output uniformity at minimal cavity thicknesses. An example of a semi-specular reflector is Vikuiti™ ESR film that has been coated with a layer of beads.

Side reflectors are also typically included in the recycling cavity to minimize loss and enhance light propagation. As mentioned elsewhere herein, the side reflectors may be partitions that divide adjacent sections of a larger zoned backlight. Furthermore, the hollow nature of the preferred recycling cavities make them readily amenable to substantial design flexibility in the design of the side reflectors. In one case, the side reflectors may simply be reflectorized walls of a cake-pan-like support unit in a simple rectangular shape. Alternatively, the side reflectors may be strips of thin reflective film, whether alone or applied to a somewhat stiffer substrate for mechanical support. In such cases, it is relatively easy to produce a cavity area that is other than rectangularly-shaped simply by bending one or more side-reflector strips into a desired shape.

This is shown in FIG. 6, where reference numeral 60 identifies a backlight output area of conventional rectangular design. An irregularly shaped side reflector 62, formed for example by bending a strip of reflective material and placing it between the (rectangular- or otherwise-shaped) front and back reflectors, produces an output area with an irregular right edge. Other edges of the output area may be similarly shaped to provide a wide variety of non-rectangular output area shapes, e.g., oval.

For illustrative purposes, it is convenient to further define the optical surfaces of the backlight front reflector and back reflector, which form the recycling cavity. FIG. 7 is a schematic cross-section view of a display system 700 that includes a backlight 710 and an LC panel 730. The backlight 710 is positioned to provide light to the LC panel 730. The backlight 710 includes a front reflector 712 and a back reflector 714 that form a hollow light recycling cavity 716 having a cavity depth H and an output region 718 of area Aout. The front reflector 712 includes first, second, and third front reflector films 720, 722, 724, that form the front reflector film stack. Any suitable films described herein can be utilized to provide the front reflector 712.

The LC panel 730 typically includes a layer of LC 736 disposed between panel plates 738. The plates 738 are often formed of glass and may include electrode structures and alignment layers on their inner surfaces for controlling the orientation of the liquid crystals in the LC layer 736. These electrode structures are commonly arranged so as to define LC panel pixels, i.e., areas of the LC layer where the orientation of the liquid crystals can be controlled independently of adjacent areas. A color filter 740 may also be included with one or more of the plates 738 for imposing color on the image displayed by the LC panel 730.

The LC panel 730 is positioned between an upper absorbing polarizer 732 and a lower absorbing polarizer 734. In the illustrated embodiment, the upper and lower absorbing polarizers 732, 734 are located outside the LC panel 730. The absorbing polarizers 732, 734 and the LC panel 730 in combination control the transmission of light from a backlight 710 through the display system 700 to the viewer. For example, the absorbing polarizers 732, 734 may be arranged with their transmission axes perpendicular to each other. In an unactivated state, a pixel of the LC layer 736 may not change the polarization of light passing therethrough. Accordingly, light that passes through the lower absorbing polarizer 734 is absorbed by the upper absorbing polarizer 732. When the pixel is activated, the polarization of the light passing therethrough is rotated so that at least some of the light that is transmitted through the lower absorbing polarizer 734 is also transmitted through the upper absorbing polarizer 732. Selective activation of the different pixels of the LC layer 736, for example, by a controller (not shown), results in the light passing out of the display system 700 at certain desired locations, thus forming an image seen by the viewer. The controller may include, for example, a computer or a television controller that receives and displays television images.

One or more optional layers (not shown) may be provided proximate the upper absorbing polarizer 734, for example, to provide mechanical and/or environmental protection to the display surface. In one exemplary embodiment, the layer may include a hardcoat over the upper absorbing polarizer 734.

It will be appreciated that some types of LC displays may operate in a manner different from that described above. For example, the absorbing polarizers 732, 734 may be aligned parallel and the LC panel may rotate the polarization of the light when in an unactivated state. Regardless, the basic structure of such displays remains similar to that described above.

For modeling purposes in which we consider the front and back reflector to be of substantially infinite extent, we can define a back reflector effective reflectivity for visible unpolarized light, “R^(b) _(hemi)(effective),” as including all of the reflective and lossy elements within the interior of the recycling cavity other than the aperture defining the output surface. In this regard, lossy elements such as LED dies, lenses, packaging, circuitry, and exposed circuit board, are included in an area-fraction sense, with the surrounding high-reflectivity materials, to determine R^(b) _(hemi)(effective). Further, physical gaps between reflective surfaces are also included in defining this effective reflectivity. The physical location of this R^(b) _(hemi)(effective) surface can then be conveniently drawn as coincident with the mean surface of the physical cavity interior.

Further, it is convenient to define the optical properties of the front reflector using the simple constructs R^(f) _(hemi), and T^(useable)(0 deg), where “useable” (sometimes illustrated with the symbol “∥”) refers to the polarization state that is aligned with the pass-axis of the bottom absorbing polarizer 734 of an application LCD panel 730 (shown above the backlight in FIG. 7).

R^(f) _(hemi) is a measurable quantity, describing the hemispherical reflectivity of the front reflector. This front reflector can be configured to consist of a single reflective film or numerous combinations of reflective films or reflective elements. They may be laminated or spaced apart, but in general they are defined as components that are co-extensive with the output face of the cavity and operate together as a system to recycle light from the sources in order to thoroughly mix the light within the cavity. The components of the front reflector can include diffusive elements such as diffuser plates, and surface structure diffusers, as well as refractive elements such as lenticular and/or prismatic films.

The value of T^(useable)(0 deg) is defined as the ratio of the transmitted intensity at 0 degrees (normal to the front reflector plane) with the front reflector and an absorbing polarizer overlaying an all-angle light source (e.g., an angle-mixed recycling cavity), to the intensity at 0 degrees for just the absorbing polarizer overlaying the all-angle light source. In instances where the display application is designed to accept light of some other set of angles other than the normal angle, 0 degrees, or some arbitrary polarization state, the characteristic optical property of the front reflector can be more generally specified by T_(pol) (Ω), where Ω represents the solid angle of application acceptance of light from the output area of the backlight, and “pol” refers to the polarization state of that light, which is required for application utility.

In reference to FIG. 7, it is further convenient to define the front reflector 712 as a surface with properties R^(f) _(hemi), residing at an inner-most surface 726 of the front reflector film, or the inner-most reflective component of the front reflector component stack, and T^(pol) (Ω) residing at an outer-most surface 728 of the front reflector film, or the outer-most reflective component of the front reflector component stack. The backlight cavity depth H, can then be defined by the perpendicular distance from the R^(b) _(hemi)(effective) surface, and the front reflector innermost surface 726 with property R^(f) _(hemi). For other arbitrary backlight cavity geometries, where the back reflector R^(b) _(hemi)(effective) surface 716 and the front reflector R^(f) _(hemi) surface 726 are not co-planar, an effective cavity depth H_(eff) can be defined using appropriate geometrical constructs.

In many cases, it is desirable to combine high-recycling properties of a backlight cavity having a product R^(f) _(hemi)*R^(b) _(hemi)(effective) of at least 0.70, and preferably at least 0.80, and most preferably at least 0.90, with sufficiently high values of T^(pol)(Ω), as this provides the angle-mixed and spatially mixed light within the cavity, an escape mechanism across the output area, for delivering spatially uniform brightness to the application.

In instances where the application requires light of a certain polarization, such as an LCD panel, sufficiently high values of T^(useable)(0 deg) may be needed to achieve high LCD-usable brightness across an application viewer-cone that is distributed about the normal direction. Indeed, with the advent of new solid-state, high brightness LED light sources, the dual challenge of transforming the high-brightness LED light generation surfaces into large-area, spatially uniform output surfaces of required brightness, without the loss of significant portions of LED emitted light, has become formidable. We therefore describe herein hollow backlights with unique geometrical properties SEP/H and Aemit/Aout that have adequate brightness and spatial uniformity for an intended application. This is achieved by the surprising approach of employing backlight cavities with very high reflective surfaces front and back, in combination with a balance of these reflective surfaces' specular and diffuse characteristics, and with light injection optics that partially collimate or confine light initially injected into the recycling cavity to propagation directions close to a transverse plane (the transverse plane being parallel to the output area of the backlight). In addition, we have found that by use of unique front reflector T^(pol)(Ω) properties, high-application brightness of application-usable polarization can be achieved.

To a good approximation, a suitably designed optical cavity in which a large proportion of the light emitted by internal light sources undergoes multiple reflections between substantially coextensive front and back reflectors, will have light rays within the cavity that can become substantially randomized in both direction and spatial location within the cavity. The number of multiple reflections required to achieve this spatial and angular randomization of the light rays will depend to a large extent on the specular and diffusive characteristics for the reflective elements (see, e.g., the 63032 Application).

For a recycling backlight cavity with a high degree of angular and spatial randomization of light rays within the cavity, the brightness through the output surface into any particular output angle Ω will be substantially equal at various points along the output surface. For such a recycling cavity, the brightness into any particular output angle Ω can be approximated by the expression

L(Ω)=((Light Source Lumens)/(2π×A _(out)))*(T ^(pol)(Ω)/(1−R ^(f) _(hemi) ×R ^(b) _(hemi)(effective))).

The “Light Source Lumens” is that which is emitted into the cavity by the light sources disposed within or optically coupled to the cavity. The expression T^(pol)(Ω)/(1−R^(f) _(hemi)×R^(b) _(hemi)(effective)) represents the fractional increase in intensity into a solid angle Ω, of polarization “pol,” for the recycling cavity with front and back reflectors, compared with an angle-mixed flux into the forwards hemisphere (relative to the output surface) of the light sources alone.

We have found that LED light-source attributes and light injection geometries, in combination with novel high reflection materials, with appropriate front reflector transmission characteristics, can be configured to enable substantially hollow backlights in novel regions of backlight parameter space.

Component Characterization

We have measured R^(b) _(hemi) for several materials that have current and potential uses as back reflector components. The measurement apparatus employed was custom-built by the Applicants but is straightforward in design and operation. A commercial six inch integrating sphere manufactured by Labsphere and made of Spectralon, with three mutually orthogonal ports, is used to illuminate samples and to determine hemispherical reflectance, R_(hemi), as well as normal-angle transmittance T^(useable)(0 deg), for front reflector and back reflector samples. A stabilized light source illuminates the sphere through one port. A PhotoResearch PR650 spectrophotometer is used to measure the sphere internal wall radiance through a second port. The sample is placed on the third port. Calibration of the integrating sphere wall radiance is done by using a known reflectance standard placed on the third port, and sphere-wall radiance is measured with and without the calibration standard. R_(hemi) is measured by placing samples on the third port; sample hemispheric reflectance R_(hemi) is obtained by taking the ratio of the sphere wall radiance with and without the sample and employing a simple integrating sphere brightness-gain algorithm. This measurement of R_(hemi) is germane to recycling backlight cavity performance in that it is the all-angle input, all-angle output reflection, measured in a way much like that which occurs in an actual recycling cavity. Further, transmittance into a chosen solid angle T(Ω), where Ω is defined by the collection aperture and its location relative to the normal to the sample surface, is collected using the PhotoResearch PR650 spectrophotometer at the third port. The LCD-usable transmittance at normal angle T^(useable)(0 deg) is obtained by using the spectrophotometer at normal angle to the sample and referencing the sample and overlaying absorbing polarizer (LCD display polarizer SR5518, from San Ritz), to the absorbing polarizer alone.

Using the above described technique, R^(b) _(hemi) was determined for the following materials:

TABLE I Reflection Ref letter Material characteristic R^(b) _(hemi) A 3M Vikuiti ESR Specular 99.4% B MC-PET Near-Lambertian 98.4% diffuse C 3M 2xTiPS Near-Lambertian 97.5% diffuse D 3M BGD ESR Semi-specular 98.0%

ESR is Vikuiti™ Enhanced Specular Reflector multilayer polymeric film available from 3M Company. ESR had a hemispherical reflectivity of 99.4%.

MC-PET is a microcellular PET reflective sheeting, available from Furukawa America, Inc. (Peachtree City, Ga.). MCPET is diffusely reflective.

2×TIPS is a porous polypropylene film having a high reflectivity and can be made using thermally induced phase separation as described, e.g., in U.S. Pat. No. 5,976,686 (Kaytor et al.). Two sheets of TIPS were laminated together using an optical adhesive to form a laminate. The Lambertian diffuse reflector had an average hemispherical reflectivity of 97.5%.

3M BDG ESR is an optical film that included a plurality of optical elements coated onto an ESR film. The coating process included dispersing a size distribution with geometric mean diameter of ˜18 μm, of small PMMA beads (MBX-20, available from Sekisui) into a solution of Iragacure 142437-73-01, IPA, and Cognis Photomer 6010. The solution was metered into a coater, and subsequently UV cured, producing a dried coating thickness of approximately 40 μm. At this thickness, the dispersion of PMMA beads created a partial of hemispheric surface structure, randomly distributed spatially. The average radius of protrusion of the PMMA beads above the mean surface was estimated to be approximately 60% of the average bead radius. The dried matrix was formulated to have approximately the same refractive index as the PMMA beads, minimizing the bulk scattering within the coating. BESR had a hemispherical reflectivity of 98.0%.

Further characterizations were performed using the techniques referenced above on the materials potentially suitable for use as front reflectors, either single reflective films or combinations of reflective elements and diffusive elements. The results of these characterizations are listed in the following table:

TABLE II Reflection Material characteristic R^(f) _(hemi) T^(useable) (0 deg) Astra DR55 Lambertian 43.9% 55.6% (DP) DP + DBEF-Q Lambertian 62.8% 63.1% DP + ARF-37 Lambertian 73.2% 50.0% DP + 3xARF Lambertian 78.3% 44.9% DP + GD + Lambertian 75.0% 59.0% BEF + DBEF ARF-89 Specular 92.5% 11.0% ARF-86 + Specular 92.1% 12.8% BGD (afs) ARF-84 Specular 88.5% 16.3% ARF-84 + Specular 88.5% 19.8% BGD (afs) ARF-68 Specular 83.2% 31.6% ARF-37 Specular 67.6% 61.9% 3xARF Specular 75.4% 52.0% 4xARF Specular 79.2% 44.4% 5xARF Specular 81.1% 39.6% 5xARF + BGD Semi-Specular 82.1 38.3% (ts) APF Specular 51.0 90.1% DBEF-D Semi-Specular 47.6 89.6%

89% R Asymmetric Reflective Film (ARF-89). This asymmetric reflective film included 264 alternating microlayers of birefringent 90/10 coPEN and non-birefringent PMMA. The 264 alternating microlayers were arranged in a sequence of ¼ wave layer pairs, where the thickness gradient of the layers was designed to provide a strong reflection resonance broadly and uniformly across bandwidth from approximately 400 nm to 900 nm wavelength for one polarization axis, and a weaker reflection resonance for the orthogonal axis. Five micron thick skin layers of 90/10 coPEN were disposed on the outside surfaces of the coherent altering microlayer stack. The overall thickness of the film, including the alternating microlayers, the PBLs and the skin layers, was approximately 40 microns. This film was manufactured using the methods described herein.

The birefringent refractive index values (measured at 633 nm) for the 90/10 coPEN layers were nx1=1.785, ny1=1.685, nz1=1.518, and the indices for the PMMA layers were nx2=ny2=nz2=1.494.

ARF-89 had an average on-axis reflectivity of 89% in the pass axis, an average on-axis reflectivity of 98% in the block axis, and a hemispherical reflectivity of 92.5%.

84% R Asymmetric Reflective Film (ARF-84). This asymmetric reflective film included 264 alternating microlayers of birefringent 90/10 coPEN material and non-birefringent PMMA material. The 264 alternating microlayers were arranged in a sequence of ¼ wave layer pairs, where the thickness gradient of the layers was designed to provide a strong reflection resonance broadly and uniformly across a bandwidth from approximately 400 nm to 900 nm for one polarization axis, and a weaker reflection resonance for the orthogonal axis. Five micron thick skin layers of 90/10 coPEN were disposed on the outside surfaces of the coherent altering microlayer stack. The overall thickness of ARF-84, including the alternating microlayers, the PBLs and the skin layers, was approximately 40 μm. This film was manufactured using the methods described herein.

The birefringent refractive index values (measured at 633 nm) for the alternating microlayers of 90/10 coPEN were nx1=1.785, ny1=1.685, and nz1=1.518; and the indices for the microlayers of PMMA were nx2=ny2=nz2=1.494.

ARF-84 had an average on-axis reflectivity of 83.7% in the pass axis, an average on-axis reflectivity of 97.1% in the block axis, and a hemispherical reflectivity of 88.5%.

68% R Asymmetric Reflective Film (ARF-68). This asymmetric reflective film included 274 alternating microlayers of birefringent 90/10 coPEN material and non-birefringent PMMA material. The 274 alternating microlayers were arranged in a sequence of ¼ wave layer pairs, where the thickness gradient of the layers was designed to provide a strong reflection resonance broadly and uniformly across bandwidth from approximately 400 nm to 970 nm for one polarization axis, and a weaker reflection resonance for the orthogonal axis. Five micron thick skin layers of a blend of 75% SA115 and 25% DP2554 were disposed on the outside surfaces of the coherent altering microlayer stack. The overall thickness of the asymmetric reflective film, including the alternating microlayers, the PBLs and the skin layers, was approximately 50 μm. This film was manufactured using the methods described herein.

The birefringent refractive index values for the alternating microlayers of 90/10 coPEN and of PMMA material were measured at 633 nm. The indices for the coPEN microlayers were nx1=1.820, ny1=1.615, and nz1=1.505. The index of refraction for the PMMA microlayers were nx2=ny2=nz2=1.494.

ARF-68 had an average on-axis reflectivity of 68.4% in the pass axis, an average on-axis reflectivity of 99.5% in the block axis, and a hemispherical reflectivity of 83.2%.

37% R Asymmetric Reflective Film (ARF-37). This asymmetric reflective film included 274 alternating microlayers of birefringent 90/10 coPEN and non-birefringent blend of CoPET-F and DP29341. The 274 alternating microlayers were arranged in a sequence of ¼ wave layer pairs, where the thickness gradient of the layers was designed to provide a strong reflection resonance broadly and uniformly across a bandwidth from approximately 420 nm to 850 nm for one polarization axis, and a weaker reflection resonance for the orthogonal axis. Five micron thick skin layers of coPEN 55/45/HD were disposed on the outside surfaces of the coherent altering microlayer stack. The overall thickness of ARF-37, including the alternating microlayers, the PBLs and the skin layers, is approximately 50 μm. This film was manufactured using the methods described herein.

The measured birefringent refractive index values (measured at 633 nm) for the alternating microlayers of 90/10 coPEN were nx1=1.820, ny1=1.615, and nz1=1.505, and the indices for the layers of coPET-F+DP29341 were nx2=ny2=nz2=1.542.

ARF-37 had an average on-axis reflectivity of 38.1% in the pass axis, an average on-axis reflectivity of 99.0% in the block axis, and a hemispherical reflectivity of 67.6%.

3 Layer Laminate of Asymmetric Reflective Film (3×ARF). This asymmetric reflective film included three asymmetric reflective films bonded together using two thick optical adhesive layers to form a laminate. Each film included 274 alternating microlayers of birefringent 90/10 coPEN and non-birefringent of PET-G. The 274 alternating microlayers were arranged in a sequence of ¼ wave layer pairs, where the thickness gradient of the layers was designed to provide a strong reflection resonance broadly and uniformly across a bandwidth from approximately 410 nm to 940 nm for one polarization axis, and a weaker reflection resonance for the orthogonal axis. There were no skin layers on the individual multilayer optical films. Each film was manufactured using the methods described herein. The overall thickness of 2×ARF, including the alternating microlayers, PBLs and adhesive layers, was approximately 100 μm. The birefringent refractive index values (measured at 633 nm) for the alternating microlayers of 90/10 coPEN were nx1=1.830, ny1=1.620, and nz1=1.500, and the indices for the microlayers of PET-G were nx2=ny2=nz2=1.563.

3×ARF had an average on-axis reflectivity of 48% in the pass axis, and a hemispherical reflectivity of 75.4%.

4 Layer Laminate of Asymmetric Reflective Film (4×ARF). This asymmetric reflective film included four asymmetric reflective films bonded together using three thick optical adhesive layers to form a laminate. Each film included 274 alternating microlayers of birefringent 90/10 coPEN and non-birefringent of PET-G. The 274 alternating microlayers were arranged in a sequence of ¼ wave layer pairs, where the thickness gradient of the layers was designed to provide a strong reflection resonance broadly and uniformly across a bandwidth from approximately 410 nm to 940 nm for one polarization axis, and a weaker reflection resonance for the orthogonal axis. There were no skin layers on the individual multilayer optical films. Each film was manufactured using the methods described herein. The overall thickness of 4×ARF, including the alternating microlayers, PBLs and adhesive layers, was approximately 200 μm.

The measured birefringent refractive index values (measured at 633 nm) for the alternating microlayers of 90/10 coPEN were nx1=1.830, ny1=1.620, and nz1=1.500, and the indices for the microlayers of PET-G were nx2=ny2=nz2=1.563.

4×ARF had an average on-axis reflectivity of 55.6% in the pass axis, and a hemispherical reflectivity of 79.2%.

5 Layer Laminate of Asymmetric Reflective Film (5×ARF). This multilayer optical film is included four thick optical adhesive layers used to bond five sheets of asymmetric reflective film in a laminate body. Each film included 274 alternating microlayers of birefringent 90/10 coPEN and non-birefringent of PET-G. The 274 alternating microlayers are arranged in a sequence of ¼ wave layer pairs, where the thickness gradient of the layers was designed to provide a strong reflection resonance broadly and uniformly across bandwidth from approximated 410 nm to 940 nm wavelength for one polarization axis, and a weaker reflection resonance for the orthogonal axis. There were no skin layers on the individual multilayer optical films. The overall thickness of 5×ARF, including the alternating microlayers, PBLs and adhesive layers, was approximately 260 μm. The measured (at 633 nm) birefringent refractive index values for the alternating microlayers of 90/10 coPEN material were nx1=1.830, ny1=1.620, and nz1=1.500, and the indices of the PET-G material were nx2=ny2=nz2=1.563.

In the following Examples, 5×ARF was used with an Opalus BS-702 beaded gain diffuser (available from Keiwa Corp.) laminated to the side of the surface of the 5×ARF that faced the back reflector, such that the beads (i.e., microspheres) of the gain diffuser faced toward the back reflector.

5×ARF laminated to the beaded gain diffuser had an average on-axis reflectivity of 61.7% in the pass axis, and a hemispherical reflectivity of 81.1%.

BGD. Unless otherwise specified, some of the following Examples included Opalus BS-702 beaded gain diffuser (available from Keiwa Corp.).

DBEF. Multilayer reflective polarizing film available from 3M Company. DBEF had a hemispheric reflectivity of 50.8%.

APF. Multilayer reflective polarizing film available from 3M Company. APF had a hemispheric reflectivity of 51.0%.

The recent emergence of very small-area light sources, such as LEDs, provides an opportunity to substantially increase the reflectivity levels for a recycling backlight back reflector. Indeed, because LED emission surface areas are so small compared to more conventional light sources, such as CCFLs, the vast majority of a recycling cavity back reflector surface can be composed of materials with extremely high values of R^(b) _(hemi) such as those described in Table I above. Of course, it is the R^(b) _(hemi)(effective) value for a recycling cavity that operationally will determine how efficient the cavity is in randomizing ray angles and creating a spatially uniform output-surface brightness. As stated above, the R^(b) _(hemi)(effective) value will include low reflectivity elements within the recycling cavity associated with light sources and electronics. We have characterized the effective reflectivity of a Cree X-Lamp array consisting of small packaged die RGGB LEDs, exposed circuitry, and an exposed local circuit board. The visible light reflectivity was characterized for the exposed area around and including the RGGB small die cluster, and the reflectivity was estimated at ±50% on average across the visible band. We can therefore make a reasonable assumption that R^(LED-area) _(hemi)=˜50%.

In the 63274 Application, the 66 clusters of RGB small package die were arrayed on the rectangular back surface of the recycling cavity, with 3M 2×TIPS covering the majority of the back reflector surface, and specular 3M ESR covering the rectangular box sidewalls. FIG. 8 depicts a top view of an individual cluster, with dimensions given in millimeters. Careful inspection of the geometrical arrangement of the 66 RGB die clusters, and the neighboring high reflectivity 2×TIPS material, indicated that the exposed area of material associated with the LED packaging and circuitry was ˜11.2% of the back reflector area, with the remaining 88.8% of the area covered by 2×TIPS. A simple area-fraction average of the R_(hemi) for each of the components yields a value for R^(b) _(hemi)(effective)=92.2%. This value for the recycling backlight's R^(b) _(hemi)(effective) can be validated by using the measured values shown in Table II for the front reflectors described in Examples C6, C7, C8, 27, and 28 of the 63274 Application, where a complete description of the examples can be found) and applying these measured values of T^(useable)(0 deg) and R^(f) _(hemi) to the equation for LP) above. In this instance, the LED RGB cluster luminous output was assumed to be 3.55 lumens/cluster.

FIG. 9 is referenced as indicating that the measured average luminance (0 deg) for each of the front reflector types in Examples C6, C7, C8, 27, and 28 compares well with the assumption of R^(b) _(hemi)(effective)=92.2%, as compared with other values for R^(b) _(hemi)(effective), indicating that the calculation of R^(b) _(hemi)(effective) by area-fraction weighing of the back reflector R^(b) _(hemi) components is valid. FIG. 9 also demonstrates the great and surprising impact that small changes in cavity efficiency (represented by the value of R^(b) _(hemi)(effective)) can have on backlight brightness.

Other recycling backlight designs that take advantage of further reductions in the low-reflectivity material area-fraction of the back reflector can be quite advantageous in providing significant improvements in light ray angular and spatial mixing, with lower losses of light to the application through the front output surface. This is particularly the case for recycling backlight architectures that employ large-package LED dies in which die sizes are on the order of 1 mm-sq. In such an instance, the area-fraction of low reflectivity material associated with LED light source disposition within or along the perimeter of the recycling cavity can be significantly diminished. Depending on the choice of back reflector components, the value of R^(b) _(hemi)(effective) can exceed 96%, and preferably 97%, and more preferably 98%.

Preface to Examples Uniformity

A wide assortment of backlights were constructed and tested as provided further below. In most cases, both the average brightness and an indication of uniformity of each backlight is provided. These results are provided so that one can assess, at least to some extent, whether the given backlight may be suitable for any particular intended application, and not necessarily limited to applications for LCD TVs or similar end-use devices.

As used herein, therefore, the term “acceptable spatial uniformity” refers to both acceptable uniformity of both overall intensity and color. What is considered acceptable brightness and spatial uniformity depends upon the particular application for which the backlight will be used. For example, a common reference standard for LCD uniformity is TCO 05 (The Swedish Confederation of Professional Employees, version 2.0, Sep. 21, 2005, p. 9), which specifies an acceptance threshold luminance ratio of greater than 66%. In the early commercialization of a particular technology, uniformity standards may be lower; for example, when notebook computers were first introduced, acceptable uniformity was in the range of 50-60%. Further, for example, internally illuminated channel letters are another application where luminance uniformity is an important performance metric. Here, human factor studies have shown that most people judge channel letter uniformity as being acceptable if the luminance ratio is greater than 50%. See, e.g., Freyssinier et al., Evaluation of light emitting diodes for signage applications, Third International Conference of Solid State Lighting, Proceedings of SPIE 5187:309-317 (2004). Emergency signage is yet another ubiquitous application for light emitting panels. An example specification for uniformity is the Energy Star program for Exit Signs. See Energy Star Program Requirements for Exit Signs Draft 1, Eligibility Criteria Version 3.0. For an exit sign to qualify for Energy Star designation, the sign should have a luminance uniformity of greater than 20:1 (i.e., 5%).

The Video Electronics Standards Association (VESA) sets guidelines for luminance and color uniformity in their publication Flat Panel Display Measurements Standard, v. 2.0 (published Jun. 1, 2001) standard 306-1 Sampled Uniformity and Color of White (herein referred to as VESA 9pt Color Nonuniformity Standard). The VESA 9pt Luminance Uniformity reported herein is determined from 9 specified circular regions (referred to as “sample points”) on the output surface of the backlight as

${{VESA}\mspace{14mu} 9{pt}\mspace{14mu} {Luminan}\; {ce}\mspace{14mu} {Uniformity}} = \frac{L_{\min}}{L_{\max}}$

where L_(min) is the minimum value of the luminance of the 9 points and L_(max) is the maximum value of the luminance of the 9 points. Higher values of VESA 9pt Luminance Uniformity indicate systems that are more uniform.

The VESA 9pt Color Nonuniformity is determined as the largest value of the color difference between any two pairs of the 9 sample points. The color difference Δu′v′ is

Δu′v′=√{square root over ((u ₁ ′−u ₂′)²+(v ₁ ′−v ₂′)²)}{square root over ((u ₁ ′−u ₂′)²+(v ₁ ′−v ₂′)²)}

where the subscripts 1 and 2 denote the two sample points being compared. Lower values of VESA 9pt Color Nonuniformity indicate systems that are more uniform.

Backlight Examples

A wide assortment of backlights were constructed and tested. The details of construction (including backlight geometry, reflective materials and other optical materials used, light sources used and their configuration, and other significant backlight components), test methodology, and results are provided in the 63274 Application cited above, and all such information is incorporated herein in its entirety. That application uses the following designation for the various embodiments constructed, and this designation is followed in the present application:

C1, C2, C3, C4, C5, C6, C7, C8; and

1, 2, 3, 4, 5, 6a through 6f, 7, 8, 9, 10a, 10b, 11a, 11b, 12a through 12f, and 13 through 31.

As will be shown below, the examples provide numerous illustrations of hollow light-recycling cavities that reside in the desired cavity design space discussed above, and provide at least adequate brightness and uniformity characteristics. Further, the examples demonstrate the effect of different combinations of reflective films for the front and back reflectors. Different light source arrangements are also included, with some being edge- and others direct-lit type. Large-area edge-lit backlights (ranging at least from 12 to 40 inch diagonal measure) are also included. Some of the examples demonstrate the effect of turning off selected light sources, showing in some cases the robustness of the design to light source failure or burnout. Finally, the examples in various combinations are submitted to demonstrate the properties called out in the claims below.

Additional Examples 21a through 21h

Some additional examples were carried out as follows. These additional examples used the same physical layout as Examples 20 and 21, except that in some cases the ARF-89 film used as the front reflector was replaced with 3M APF reflective polarizing film, and various combinations of light sources were turned on or off to demonstrate sensitivity to light source burnout. We refer to these additional examples as Examples 21a, b, c, d, e, f.

The backlight system from Examples 20 and 21 was used for these examples with the only difference being that one of the green LEDs was turned off. The green LED that was off was located at the left side of the left bank of LEDs when the box was viewed from the output side with the LED bar located along the top.

Example 21a

the output region of the Edge-Lit, Hollow Backlight was covered by a reflective polarizer (APF mounted on an acrylic plate) which was placed over the output area of the backlight. All of the LEDs (red, green, and blue, except for the single green LED mentioned above, for a total of 4R 7G 4B) were turned on to produce white light. The backlight was bright close to the LEDs and visibly darker at the far end (away from the LEDs).

Example 21b

the same configuration as for Example 21a was used, but only the green LEDs were powered (except for the single green LED mentioned above, for a total of 7G). The backlight appeared much brighter close to the LEDs and darker at the far end (away from the LEDs).

Example 21c

the same configuration as for Example 21a was used, but only the four green LEDs of the right bank of LEDs were powered (for a total of 4G). The backlight appeared much brighter on the right side close to the LEDs and was darker at the far end (away from the LEDs) and also darker on the left side where the LEDs weren't lit.

Example 21d

the same configuration as for Example 21a was used, but only the three green LEDs of the left bank of LEDs were powered (for a total of 3G). The backlight appeared much brighter on the left side close to the LEDs and was darker at the far end (away from the LEDs) and also darker on the right side where the LEDs weren't lit.

Example 21e

the output region of the Edge-Lit, Hollow Backlight was covered by a partial reflector (ARF-89 mounted on an acrylic plate) which was placed over the output area of the backlight. The partial reflector had a pass-axis transmission of approximately 11% for visible light. The back of the backlight was covered with Bead-coated ESR. All of the LEDs were turned on (red, green, and blue, except for the single green LED mentioned above, for a total of 4R 7G 4B) to produce white light. The backlight appeared uniformly illuminated.

Example 21f

the same configuration as for Example 21e was used, except only the green LEDs were powered (except for the single green LED mentioned above, for a total of 7G). The backlight appeared uniformly illuminated.

Example 21g

the same configuration as for Example 21e was used, except that only the four green LEDs of the right bank of LEDs were powered (for a total of 4G). The backlight appeared uniformly illuminated.

Example 21h

the same configuration as for Example 21e was used, except that only the three green LEDs of the left bank of LEDs were powered. The backlight appeared uniformly illuminated.

The measurement results for these examples are summarized below:

Y_Uniformity Example Y_avg Y_std [VESA9] 21a 3206 26.8% 52.8% 21b 1953 26.3% 52.8% 21c 1107 32.3% 39.7% 21d 853 33.5% 40.4% 21e 2788 7.8% 91.0% 21f 1748 8.2% 86.6% 21g 998 9.1% 78.7% 21h 768 9.2% 80.6%

From all of the foregoing examples, we have sufficient information to calculate the backlight design parameters: Parameter A, equal to Aemit/Aout; and Parameter B, equal to SEP/H.

The edge-lit examples are plotted in FIG. 10, and the direct-lit examples are plotted in FIG. 11. In both cases, the labels used in the figures correspond to the Example numbering convention above.

The various embodiments of backlights described herein can include a light sensor and feedback system to detect and control one or both of the brightness and color of light from the light sources. For example, a sensor can be located near individual light sources or clusters of sources to monitor output and provide feedback to control, maintain, or adjust a white point or color temperature. It may be beneficial to locate one or more sensors along an edge or within the cavity to sample the mixed light. In some instances it may be beneficial to provide a sensor to detect ambient light outside the display in the viewing environment, for example, the room that the display is in. Control logic can be used to appropriately adjust the output of the light sources based on ambient viewing conditions. Any suitable sensor or sensors can be used, e.g., light-to-frequency or light-to-voltage sensors (available from Texas Advanced Optoelectronic Solutions, Plano, Tex.). Additionally, thermal sensors can be used to monitor and control the output of light sources. Any of these techniques can be used to adjust light output based on operating conditions and compensation for component aging over time. Further, sensors can be used for dynamic contrast, vertical scanning or horizontal zones, or field sequential systems to supply feedback signals to the control system.

Unless otherwise indicated, references to “backlights” are also intended to apply to other extended area lighting devices that provide nominally uniform illumination in their intended application. Such other devices may provide either polarized or unpolarized outputs. Examples include light boxes, light emitting panels, signs, channel letters, visibility lights, e.g., for cars or motorcycles, and general illumination devices designed for indoor (e.g. home or office) or outdoor use, sometimes referred to as “luminaires.” Note also that edge-lit devices can be configured to emit light out of both opposed major surfaces—i.e., both out of the “front reflector” and “back reflector” referred to above—in which case both the front and back reflectors are partially transmissive. Such a device can illuminate two independent LCD panels or other graphic members placed on opposite sides of the backlight. In that case the front and back reflectors may be of the same or similar construction.

The term “LED” refers to a diode that emits light, whether visible, ultraviolet, or infrared. It includes incoherent encased or encapsulated semiconductor devices marketed as “LEDs,” whether of the conventional or super radiant variety. If the LED emits non-visible light such as ultraviolet light, and in some cases where it emits visible light, it is packaged to include a phosphor (or it may illuminate a remotely disposed phosphor) to convert short wavelength light to longer wavelength visible light, in some cases yielding a device that emits white light. An “LED die” is an LED in its most basic form, i.e., in the form of an individual component or chip made by semiconductor processing procedures. The component or chip can include electrical contacts suitable for application of power to energize the device. The individual layers and other functional elements of the component or chip are typically formed on the wafer scale, and the finished wafer can then be diced into individual piece parts to yield a multiplicity of LED dies. An LED may also include a cup-shaped reflector or other reflective substrate, encapsulating material formed into a simple dome-shaped lens or any other known shape or structure, extractor(s), and other packaging elements, which elements may be used to produce a forward-emitting, side-emitting, or other desired light output distribution.

Unless otherwise indicated, references to LEDs are also intended to apply to other sources capable of emitting bright light, whether colored or white, and whether polarized or unpolarized, in a small emitting area. Examples include semiconductor laser devices, and sources that utilize solid state laser pumping.

In some embodiments, brightness uniformity of an edge-lit backlight can be enhanced by aiming the injection light output direction, adjusting spacing between adjacent light sources or groups of light sources, or a combination of the two techniques. For example, forward emitting light sources having narrow light distribution cone angles as described herein can be selected as a way of controlling the direction of light emitted by the light sources. Typically, for edge-lit backlights, the light sources can be arranged along one or more edges of a backlight such that the emitted beams are directed substantially perpendicular to the input edge or edges and parallel to each other. By aiming the beams of one or more light sources in a non-perpendicular direction and towards selected areas of the backlight, the brightness of the selected area can be increased with a corresponding brightness decrease in other areas. For example, in a backlight having light sources uniformly disposed along one edge, the light sources can be aimed such that all of the beams intersect at the approximate center of the backlight, thus resulting in a bright center and less bright edges. If fewer than all of the beams are directed to intersect at the center, the center brightness can be decreased, thereby providing a mechanism to adjust the brightness to a desired level. Analogous arrangements can be used to produce, for example, brighter edges and a less bright center. Any suitable technique can be used to control the emission direction of the light sources, e.g., mounting orientation of the light sources, lenses, extractors, collimating reflectors, etc.

Light sources can be arranged along one or more edges of a backlight such that spacing between them is non-uniform. In this situation, the part of the backlight having more closely spaced light sources will tend to be brighter. For example, in a backlight having 40 LEDs disposed along one edge, the center 20 LEDs can be more closely spaced than the flanking 10 LEDs towards each edge, thus producing a brighter center. Analogous adjustments can be used to produce brighter edges.

This non-uniform spacing between light sources can also be provided by controlling the light output of individual or groups of light sources to simulate a non-uniform physical spacing. For example, one or more light sources can be powered down or turned off to control the distribution of injected light.

Other suitable techniques can be used either alone or in combination with light source aiming and distribution to provide a desired output light distribution. For example, uniform or non-uniform patterns of localized extraction structures can be provided on one or both of the front reflector and back reflector to redirect some of light out of the backlight.

Unless otherwise indicated, all numbers expressing feature sizes, amounts, and physical properties used in the specification and claims are to be understood as being modified by the term “about.” Accordingly, unless indicated to the contrary, the numerical parameters set forth in the foregoing specification and attached claims are approximations that can vary depending upon the desired properties sought to be obtained by those skilled in the art utilizing the teachings disclosed herein.

Various modifications and alterations of this disclosure will be apparent to those skilled in the art without departing from the scope and spirit of this disclosure, and it should be understood that this disclosure is not limited to the illustrative embodiments set forth herein. All U.S. patents, patent application publications, unpublished patent applications, and other patent and non-patent documents referred to herein are incorporated by reference in their entireties, except to the extent any subject matter therein directly contradicts the foregoing disclosure. 

1. An edge-lit backlight, comprising: a front and back reflector forming a hollow light recycling cavity having a cavity depth H and an output region of area Aout; and one or more light sources disposed proximate a periphery of the backlight to emit light into the light recycling cavity, the light sources having an average plan view source separation of SEP and collectively having an active emitting area Aemit; wherein a first parameter equals Aemit/Aout; wherein a second parameter equals SEP/H; and wherein the backlight is characterized by the first parameter being in a range from 0.0001 to 0.1, and by the second parameter being in a range from 3 to
 10. 2. The backlight of claim 1, wherein the one or more light sources comprise one or more LEDs.
 3. The backlight of claim 1, wherein the front reflector has a hemispherical reflectivity for unpolarized visible light of R^(f) _(hemi), and the back reflector has a hemispherical reflectivity for unpolarized visible light of R^(b) _(hemi), and R^(f) _(hemi)*R^(b) _(hemi) is at least 0.70.
 4. The backlight of claim 3, wherein R^(f) _(nemi)*R^(b) _(hemi) is at least 0.80.
 5. The backlight of claim 1, wherein the backlight exhibits a VESA 9 uniformity value of at least 50% over the output region.
 6. The backlight of claim 5, wherein the backlight exhibits a VESA 9 uniformity value of at least 60%.
 7. The backlight of claim 6, wherein the backlight exhibits a VESA 9 uniformity value of at least 70%.
 8. The backlight of claim 6, wherein the backlight exhibits a VESA 9 uniformity value of at least 80%.
 9. The backlight of claim 1, wherein the output region is generally rectangular and has a diagonal measure of at least 12 inches.
 10. The backlight of claim 9, wherein the diagonal measure is at least 23 inches.
 11. The backlight of claim 10, wherein the diagonal measure is at least 40 inches.
 12. An edge-lit backlight, comprising: a front and back reflector forming a hollow light recycling cavity having a cavity depth H and an output region of area Aout; and a number N of one or more light sources disposed proximate a periphery of the light recycling cavity and emitting light into the light recycling cavity; wherein the output region is generally rectangular in shape and has a diagonal measure of at least 30 inches.
 13. The backlight of claim 12, wherein the one or more light sources comprise one or more LEDs.
 14. The backlight of claim 12, wherein the output region exhibits a VESA 9 uniformity value of at least 50%.
 15. The backlight of claim 14, wherein the output region exhibits a VESA 9 uniformity value of at least 70%.
 16. The backlight of claim 12, wherein the one or more light sources have an average plan view source separation of SEP and collectively have an active emitting area Aemit; wherein a first parameter equals Aemit/Aout; wherein a second parameter equals SEP/H; and wherein the backlight is characterized by the first parameter being in a range from 0.0001 to 0.1, and by the second parameter being in a range from 3 to
 10. 17. A backlight, comprising: a front and back reflector forming a hollow light recycling cavity having an output region; and a number N of light sources disposed to emit light into the light recycling cavity, the N light sources including a subset of M light sources that are adjacent to each other, where M is at least 10% of N, or is at least 2, or both; wherein the backlight exhibits a VESA brightness uniformity value over its output region of at least 50% both when all N light sources are energized and when all of the M light sources are selectively turned off.
 18. The backlight of claim 17, wherein the recycling cavity has a depth H; wherein the output region has an area Aout; wherein the N light sources have an average plan view source separation of SEP and collectively have an active emitting area Aemit; wherein a first parameter equals Aemit/Aout; wherein a second parameter equals SEP/H; and wherein the backlight is characterized by the first parameter being in a range from 0.0001 to 0.1, and by the second parameter being in a range from 3 to
 10. 19. The backlight of claim 17, wherein the front and back reflectors are each substantially spatially uniform.
 20. The backlight of claim 17, wherein the N light sources are predominantly disposed proximate a periphery of the output region to provide an edge-lit backlight.
 21. The backlight of claim 17, wherein the front reflector has a hemispherical reflectivity for unpolarized visible light of R^(f) _(hemi), and the back reflector has a hemispherical reflectivity for unpolarized visible light of R^(b) _(hemi), and R^(f) _(hemi)*R^(b) _(hemi) is at least 0.70. 